Initialization circuit for delay locked loop

ABSTRACT

An initialization circuit in a delay locked loop ensures that after power up or other reset clock edges are received by a phase detector in the appropriate order for proper operation. After reset of the delay locked loop, the initialization circuit assures that at least one edge of a reference clock is received prior to enabling the phase detector to increase (or decrease) the delay in a delay line. After at least one edge of a feedback clock is received, the initialization circuit enables the phase detector to decrease (or increase) the delay in a delay line.

RELATED APPLICATION(S)

This application is a continuation of U.S. application Ser. No.12/639,531, filed Dec. 16, 2009, which is a continuation of U.S.application Ser. No. 12/315,289, filed Dec. 2, 2008 (now U.S. Pat. No.7,656,988), which is a continuation of U.S. application Ser. No.10/647,664, filed Aug. 25, 2003 (now U.S. Pat. No. 7,477,716), whichclaims the benefit of U.S. Provisional Application No. 60/482,260, filedon Jun. 25, 2003.

The entire teachings of the above applications are incorporated hereinby reference.

BACKGROUND OF THE INVENTION

A Delay Locked Loop (DLL) with an adjustable delay line is used tosynchronize a first clock signal with a second clock signal by delayingthe first clock signal. The DLL includes a phase detector, which detectsthe phase difference between the first clock signal and the second clocksignal. Based on the detected phase difference, the DLL synchronizes thefirst clock signal to the external clock signal by adding an appropriatedelay to the first clock signal until the second clock signal is inphase with the first clock signal.

FIG. 1 is a block diagram of a prior art DLL 100. An externally suppliedclock (CLK) is buffered by clock buffer 101 to provide a reference clock(CLK_REF) that is coupled to a voltage controlled delay line 102 and aphase detector 104. The voltage controlled delay line 102 produces anoutput clock (CLK OUT), which is a delayed version of CLK_REF and isrouted to various circuits within the device and to the replica delaycircuit 103. The replica delay circuit 103 provides a delay similar tothe delay through buffer 101 and wire routing delays. Replica delays arewell-known to those skilled in the art. See commonly owned U.S. Pat. No.5,796,673 to Foss et al for further explanation of replica delays. Afeedback clock signal CLK_FB output from the replica delay circuit 103is coupled to the phase detector 104. Other prior art DLLs use a digitaldelay line or a tapped delay line. Commonly owned U.S. Pat. Nos.5,796,673 and 6,087,868 describe such DLLs

The phase detector 104 generates phase control signals (UP, DOWN)dependent on the phase difference between CLK_REF and CLK_FB. The DOWNsignal is set to a logic ‘1’ on each CLK_REF rising edge and the UPsignal is set to a logic ‘1’ on each CLK_FB rising edge. Both UP andDOWN signals are reset to logic ‘0’ when the second rising edge of thetwo signals is received. Thus, when the CLK_REF rising edge is detectedbefore the CLK_FB rising edge, the DOWN signal transitions to a logic‘0’ to decrease the delay in the voltage controlled delay line (VCDL)102 until the next rising edge of the CLK_FB is detected. Alternatively,if CLK_FB rising edge is detected prior to the CLK_REF rising edge, theUP signal is asserted (logic ‘1’) to increase the delay until the nextrising edge of CLK_REF is detected.

The phase control signals (UP/DOWN) of the phase detector 104 areintegrated by a charge pump 105 and a loop filter 106 to provide avariable bias voltage V_(CTRL) 110 for the VCDL 110. The bias voltageV_(CTRL) selects the delay to be added to CLK_REF by the VCDL 102 tosynchronize CLK_FB with CLK_REF.

-   -   The phase detector 100 may be level sensitive or edge triggered.        Typically, edge triggered phase detectors are used because level        sensitive phase detectors are susceptible to false locking.        However, the clock is free running, and it is not known which        clock edge will occur first after a reset. Thus, dependent on        the initial phase relationship between the input signals to the        phase detector (i.e. dependent on whether the rising edge of the        CLK_REF or CLK_FB occurs first after system reset or power up).        The UP (DOWN) signal may be triggered first when the delay        should be decreased (increased), so DLLs with edge triggered        phase detectors may never achieve lock.

FIG. 2 is a schematic diagram of a prior art edge triggered phasedetector 104. The phase detector 104 detects the phase differencebetween CLK_REF and CLK_FB and sets the UP, DOWN signals to logic ‘1’dependent on the phase difference to increase or decrease the delay. Thephase detector 104 includes two rising edge triggered D-type Flip-Flops(DFF) 201, 203 and a reset circuit 210. The input of each DFF 201, 203is coupled to V_(DD) and the respective asynchronous reset input of eachDFF 201, 203 is coupled to the output (RSTb) of the reset circuit 210.The reset circuit 210 generates a logic ‘0’ on the RSTb signal to resetDFFs 201, 203 when the RESETb signal is at a logic ‘0’ or when both theUP and DOWN signals are at a logic ‘1’.

The clock input of each DFF is coupled to a respective one of the inputsignals (CLK_REF, CLK_FB), with the clock input of DFF 201 coupled toCLK_REF and the clock input of DFF 203 coupled to CLK_FB. The output ofeach DFF 201, 203 is coupled to respective UP/DOWN inputs of charge pump105 (FIG. 1) to increase or decrease the delay of the VCDL 102 based onthe detected phase difference between the clocks.

If a rising edge (transition from a logic ‘0’ to a logic ‘1’) of CLK_REFis detected prior to a rising edge of CLK_FB, the delay is decreased.For example, if the rising edge of CLK_REF occurs before the rising edgeof CLK_FB, the DOWN signal is asserted (i.e. the output of DFF 201changes to a logic ‘1’) to decrease the delay. While the DOWN signal isat logic ‘1’, the charge pump and loop filter decrease the delay in theVCDL 102. The DOWN signal remains at a logic ‘1’ until a subsequentrising edge of CLK_FB clocks DFF 203 and the UP signal at the output ofDFF 203 transitions from a logic ‘0’ to a logic ‘1’. With both UP andDOWN signals at a logic ‘1’, the reset circuit 210 generates a logic ‘0’pulse on the RSTb signal. The logic ‘0’ pulse on the RSTb signal coupledto the asynchronous reset inputs of DFF 201, 203 resets DFF 201, 203 andthe UP and DOWN signals are reset to a logic ‘0’.

If the rising edge of CLK_FB is detected prior to the rising edge ofCLK_REF, the delay is increased, the UP signal transitions from a logic‘0’ to a logic ‘1’. While the UP signal is at a logic ‘1’, the chargepump and loop filter increase the delay through the delay line. The UPsignal is held at a logic ‘1’ until the rising edge of CLK_REF clocksDFF 203 and the DOWN signal transitions to a logic ‘1’. With both UP andDOWN signals asserted (at a logic ‘1’), the reset circuit 210 generatesa logic ‘0’ pulse on the RSTb signal and DFFs 201, 203 are reset. Afterthe DFFs 201,203 are reset, the UP and DOWN signals at the outputs ofDFFs are reset to a logic ‘0’.

-   -   After a power up or system reset, the voltage controlled delay        line is typically set to a minimum delay. If after reset or        power up, the rising edge of the CLK_REF signal occurs prior to        the rising edge of the CLK_FB signal, the phase detector 104        will set the DOWN signal to a logic ‘1’ to decrease the delay.        However, the delay will already be at the minimum allowed. Thus,        all subsequent phase detector cycles will continue to try to        decrease the DLL delay and the DLL will never achieve lock.

FIG. 3 is a timing diagram that illustrates a clock edge orderingproblem after reset. The problem with achieving lock arises when therising edge of CLK_REF occurs prior to the rising edge of CLK_FB. In theexample shown, the rising edge of CLK_REF occurs at the same time as thefalling edge of CLK_FB. However, the phase difference is variable andboth rising edges may even occur at the same time. FIG. 3 is describedin conjunction with the circuit shown in FIG. 2. During reset, theRESETb signal is held at a logic ‘0’ and the delay in the voltagecontrolled delay line is set to a minimum delay (one unit delay cell).Also, signals UP and DOWN are both held at a logic ‘0’ because DFFs 201,203 are held reset by a logic ‘0’ on the RESETb signal.

At time 200, the RESETb signal transitions from a logic ‘0’ to a logic‘1’. As shown, after reset the rising edge of CLK_REF occurs followed bythe rising edge of CLK_FB.

At time 202, the first rising edge (from a logic ‘0’ to a logic ‘1’) onthe CLK_REF signal sets DFF 201 and the DOWN signal (the output of DFF201) is set to a logic ‘1’. While the DOWN signal is at a logic ‘1’, thedelay in the delay line is decreased. However the DLL delay is alreadyat the minimum value set while RESETb was at a logic ‘0’. Thus, thelogic ‘1’ on the DOWN signal has no effect on the delay of VCDL.

At time 204, the rising edge detected on the CLK_FB signal sets DFF 203resulting in setting the UP signal (the output of DFF 203) to a logic‘1’. With both the UP signal and the DOWN signal at a logic ‘1’, thereset circuit 210 generates a logic ‘0’ pulse on the RSTb signal toreset both DFFs 201, 203 and the UP and DOWN signals to a logic ‘0’ attime 206.

This sequence is repeated starting with the next rising edge of CLK_REFat time 208 and continues for each subsequent rising edge of CLK_REF andCLK_FB. The delay remains stuck at the minimum delay, and thus, the DLLnever achieves lock.

SUMMARY OF THE INVENTION

An initialization circuit in a delay locked loop that ensures properordering of clock signals to a phase detector after reset is presented.The delay locked loop includes a delay circuit that provides a delay toa reference clock to generate a feedback clock. The delay circuit has adelay range. A phase detector in the delay locked loop compares phase ofthe reference clock and the feedback clock to change the delay of thedelay circuit. After reset, the initialization circuit assures that thephase detector initially change the delay in a direction away from afirst end of the delay range after receipt of one of the reference clockand the feedback clock and enables a change in the delay in an oppositedirection toward the first end only after receipt of one of thereference clock and the feedback clock followed by receipt of the otherof the reference clock and the feedback clock.

The first end of the delay range may be a minimum delay and thedirection away from the first end increases the delay and the oppositedirection towards the first end decreases the delay. The initializationcircuit increases the delay after receipt of the reference clock andenables decrease in the delay only after receipt of the reference clockfollowed by the feedback clock. The initialization circuit may include afirst latch and a second latch with the input of the second latchcoupled to the output of the first latch. The first latch is responsiveto the reference clock and detects a first edge of the reference clockto enable change in the delay in the direction away from the first end.The second latch is responsive to the feedback clock and detects an edgeof the feedback clock after the first edge of the reference clock hasbeen detected by the first latch, to enable change in the delay in theopposite direction.

In an alternate embodiment, further delay may added to allow the clocksto stabilize by adding two latches to the initialization circuit. Theinput of a third latch is coupled to the output of the first latch andthe input of a fourth latch is coupled to the output of the third latch.The third latch detects a next edge of the reference clock to delay theenabling of the phase detection circuit in the first direction for atleast one reference clock period. The fourth latch detects a next edgeof the feedback clock to delay the enabling of the adjustment of thephase detector in the other direction for at least one feedback clockperiod.

The first edge of the reference clock may be a rising edge and the edgeof the feedback clock is a rising edge.

In an alternate embodiment, the initialization circuit may include afirst latch and a second latch. The first latch is responsive to thefeedback clock and detects a first edge of the feedback clock to enablechange in the delay in the direction away from the first end. The secondlatch is responsive to the reference clock, which detects an edge of thereference clock after the first edge of the feedback clock has beendetected by the first latch to enable change in the delay in theopposite direction. The input of the second latch coupled to the outputof the first latch.

The phase detector may include a latch responsive to the reference clockto generate a first phase control signal and another latch responsive tothe feedback clock to generate a second phase control signal.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other objects, features and advantages of theinvention will be apparent from the following more particulardescription of preferred embodiments of the invention, as illustrated inthe accompanying drawings in which like reference characters refer tothe same parts throughout the different views. The drawings are notnecessarily to scale, emphasis instead being placed upon illustratingthe principles of the invention.

FIG. 1 is a block diagram of a typical prior art delay locked loop(DLL);

FIG. 2 is a schematic diagram of a typical prior art phase detector;

FIG. 3 is a timing diagram that illustrates a clock edge orderingproblem after reset;

FIG. 4 is a schematic diagram of an edge triggered phase detectioncircuit including phase detector initialization circuit according to theprinciples of the present invention;

FIG. 5 is a circuit diagram of an embodiment of the reset circuit shownin FIG. 4;

FIG. 6 is a timing diagram that illustrates the operation of the circuitshown in FIGS. 4 and 5;

FIG. 7 is a timing diagram illustrating the operation of the circuitshown in FIG. 4 when the rising edge of the feedback clock precedes therising edge of the reference clock after reset;

FIG. 8 is a schematic diagram of an alternate embodiment of the phasedetection circuit shown in FIG. 4 for use in a DLL in which the delay isreset to the maximum value at reset;

FIG. 9 is a schematic diagram of an alternate embodiment of the phasedetector initialization circuit;

FIG. 10 is yet another embodiment of the phase detector initializationcircuit; and

FIG. 11 is a timing diagram illustrating the operation of the circuit ofFIG. 9 when the rising edge of the reference clock precedes the risingedge of the feedback clock.

DETAILED DESCRIPTION OF THE INVENTION

A description of preferred embodiments of the invention follows.

FIG. 4 is a schematic diagram of an edge triggered phase detectioncircuit 400 including phase detector initialization circuit 410according to the principles of the present invention. The phasedetection circuit 400 replaces the phase detector 104 of FIG. 1 toprovide a novel DLL. The phase detection circuit 400 includes a phasedetector 412 that detects the phase difference between a reference clock(CLK_REF) signal and a feedback clock (CLK_FB) signal. The outputs (UP,DOWN) of the phase detector 412 are coupled to respective UP/DOWN inputsof a charge pump as described in conjunction with the phase detector 104shown in FIG. 1 to increase or decrease the delay of the reference clockbased on the detected phase difference between the clocks.

The delay can range from a minimum value to a maximum value. In avoltage controlled delay line the control voltage has a range of allowedvalues. One end of that range corresponds to a minimum delay value forthe VCDL and the other end of that range corresponds to a maximum delayvalue for the VCDL. The operation of a VCDL is well understood in theart and will not be discussed further. Other DLLs which use a digitaldelay line have a minimum delay value usually equal to one unit delay inthe digital delay line and a maximum delay value usually equal to thenumber of unit delays in the digital delay line. In the embodimentshown, the delay of the DLL is reset to the minimum value at reset. Thephase detector initialization circuit 410 coupled to the phase detector412 at node A and node B ensures the correct ordering of the detectionof clock edges after reset.

To ensure correct ordering, the phase detector initialization circuit410 disables the operation of the phase detector 412 until after thefirst rising edge of the CLK_REF has been detected after reset. Afterthe phase detector initialization circuit 410 detects the first risingedge of CLK_REF, the state of the phase detector 412 is set to allow anincrease in the DLL delay. The phase detector initialization circuit 410further delays enabling a decrease of the delay by the phase detector412 until the next CLK_FB rising edge to ensure that the delay is alwaysincreased after a system or power up reset even when there is no initialphase difference between the clocks. After the initial increase in thedelay, the phase detector 412 operates as described in conjunction withthe prior art phase detector described in conjunction with FIGS. 2 and3. By detecting the rising edge of CLK_REF first after reset, anddelaying the detection of the first rising edge of CLK_FB prior toenabling phase detection, the delay is always increased after reset. Byalways automatically increasing the delay after reset, the no-lockcondition in the prior art phase detector described in conjunction withFIGS. 2 and 3 is never encountered.

The phase detector initialization circuit 410 includes two DFFs 404,403. DFF 404 detects the first rising edge of CLK_REF after reset andenables an increase in the delay by setting node A to a logic ‘1’. DFF403 delays enabling a decrease in the delay by holding node B at a logic‘0’ until after the next rising edge of CLK_FB.

The phase detection circuit 402 includes two DFFs 401, 402 and resetcircuit 416. The output of DFF 404 (node A) is coupled to the D input ofDFF 402 and the output of DFF 403 (node B) is coupled to the D input ofDFF 401. The respective asynchronous reset input of each DFF 401, 402 iscoupled to the output (RSTb) of the reset circuit 416. The RSTb signalis set to a logic ‘0’ to reset DFFs 401,402 during a reset while theRESETb signal is held at a logic ‘0’ or while both the UP and DOWNsignals are at a logic ‘1’.

The clock input of each DFF 401, 402 is coupled to a respective one ofthe input clock signals (CLK_REF, CLK_FB), with the clock input of DFF401 coupled to CLK_REF and the clock input of DFF 402 coupled to CLK_FB.The output of each DFF 401, 402 is coupled to respective UP/DOWN inputsof a charge pump to increase or decrease the delay based on the detectedphase difference between the clocks.

FIG. 5 is a circuit diagram of an embodiment of the reset circuit 416shown in FIG. 4. The reset circuit 416 includes a plurality of inverters215, 213, 212, 217, a NAND gate 216 and an AND-OR-INVERTER 211. A truthtable describing the operation of the reset circuit is shown in Table 1below.

TABLE 1 INPUTS OUTPUT UP DOWN RESETb RSTb X X 0 0 0 1 X 1 1 0 X 1 1 1 X0

During reset the RESETb signal is set to a logic ‘0’ and the RSTb signalis set to a logic ‘0’ at the input of inverter 217. The logic ‘1’ at theoutput of inverter 217 coupled to one of the inputs of theAND-OR-INVERTER 211 results in a logic ‘0’ on the RSTb signal.

When both the UP and DOWN outputs of the phase detector circuit 412transition to a logic ‘1’, the RSTb signal is set to a logic ‘0’ for thelength of time equal to the propagation delay through inverters 212,213, 214. The output of inverter 212 is at a logic ‘1’ prior to both theDOWN and UP signals transitioning to a logic ‘1’ at the inputs of NANDgate 216. With both inputs of NAND gate 216 at a logic ‘1’, the outputof NAND gate 216 transitions to a logic ‘0’. The logic ‘0’ at the inputof inverter 215 results in a logic ‘1’ at the output of inverter 215coupled to the input of AND-OR-INVERTER 211. With both inputs ofAND-OR-INVERTER 211 at a logic ‘1’, the RSTb signal transitions to alogic ‘0’. The RSTb signal transitions back to a logic ‘1’ after thelogic ‘1’ on the input of inverter 214 propagates through inverters 213,212 resulting in a logic ‘0’ on the input of AND-OR-INVERTER 211 coupledto the output of inverter 212. This results in a logic ‘0’ pulse on theRSTb signal.

The operation of the circuit shown in FIGS. 4 and 5 is described inconjunction with the timing diagrams shown in FIG. 6 and FIG. 7. FIG. 6illustrates the case when the rising edge of the reference clockprecedes the rising edge of the feedback clock after reset and FIG. 7illustrates the case when the rising edge of the feedback clock precedesthe rising edge of the reference clock after reset.

FIG. 6 is a timing diagram that illustrates the operation of the circuitshown in FIGS. 4 and 5.

The outputs of DFFs 403, 404 are coupled at nodes B and A to respectiveD-inputs of DFFs 401, 402. Prior to time 500 in FIG. 6, during reset,the RESETb signal is held at a logic ‘0’ and the delay in the voltagecontrolled delay line is set to a minimum delay. In a wide frequencyrange DLL the minimum delay of the delay line may be greater than theperiod of CLK_REF. While the RESETb signal and RSTb signal are at alogic ‘0’ and there is a logic ‘0’ on the respective D-inputs of DFFs401, 402, 403, a rising edge on the CLK_FB signal or the CLK_REF signalhas no effect on the output signals (UP, DOWN).

RSTb is coupled to the respective asynchronous reset inputs of DFFs 401,402 and RESETb is coupled to the respective asynchronous reset inputs ofDFFs 403, 404. Nodes A and B are held at a logic ‘0’ signals becauseDFFs 403, 404 are held reset by the RESETb signal. Also, UP and DOWNsignals at the output of DFFs 401, 402 are both held at a logic ‘0’because the RSTB signal output by the reset circuit 410 is held at alogic ‘0’ while RESETb is at a logic ‘0’ as described in conjunctionwith FIG. 5.

At the end of the reset cycle, at time 500, the RESETb signaltransitions to a logic ‘1’ allowing DFFs 404, 403 to change state. Afterreset, the first rising edge (transition from logic ‘0’ to logic ‘1’) ofCLK_REF occurs before the first rising edge of the CLK_FB signal.

At time 502, the first rising edge on the CLK_REF signal sets DFF 404and the signal at node A (the output of DFF 404) transitions from alogic ‘0’ to a logic ‘1’. A logic ‘1’ on node A allows DFF 402 to setthe UP signal to increase the delay after the next rising edge of CLK_FBis detected.

At time 504, the first rising edge of CLK_FB sets DFF 402 and the UPsignal (the output of DFF 402) transitions from a logic ‘0’ to a logic‘1’. The first rising edge of CLK_FB also sets DFF 403 and the signal atnode B (the output of DFF 403) transitions from a logic ‘0’ to a logic‘1’ allowing the delay to be decreased on the next rising edge ofCLK_REF. While the UP signal is at logic ‘1’, the delay is increased.

DFF 403 in the phase detector initialization circuit 410 ensures thatthe delay will always be increased after a reset even if there is noinitial phase difference between the signals (CLK_REF and CLK_FB). Thetime that the UP signal is held at a logic ‘1’ prior to the DOWN signalbeing set to a logic ‘1’ by DFF 401 is dependent on the initial phasedifference between the CLK_FB and CLK_REF.

At time 505, with a logic ‘1’ at the D-input of DFF 401, the rising edgeof CLK_REF latches a logic ‘1’ at the output of DFF 401. With bothoutputs (DOWN, UP) of DFFs 401, 402 at a logic ‘1’, a logic ‘0’ pulse isgenerated on the RSTb signal by the reset circuit 416 to reset DFFs401,402. At time 506, both DFFs 401, 402 are reset and both outputs(DOWN, UP) are reset to logic ‘0’. DFFs 403, 404 are not reset. Instead,they remain in the set state with logic ‘1’ on the respective outputs atnodes A, B until the next reset is detected.

Thus, after the initial increase in the delay, the phase detector 412controls the generation of the phase control signals (UP/DOWN) tofurther increase or decrease the delay until lock is achieved. The phasedetector 412 continues to increase the delay by generating further UPsignal transitions as shown at time 508 and 510 until at time 512 theDLL is in the lock state. The phase detector 412 continuously monitorsthe phase difference between the CLK_REF signal and the CLK_FB signaland adjusts the delay by setting the UP/DOWN signals appropriately toachieve lock.

FIG. 7 is a timing diagram illustrating the operation of the circuitshown in FIG. 4 when the first rising edge of the feedback clock occursbefore the first rising edge of the reference clock after reset.

At time 700, the RESETb signal transitions from a logic ‘0’ to a logic‘1’. At time 701, the rising edge of CLK_FB is ignored by DFFs 403, 402because the first rising edge of CLK_REF has not yet been detected byDFF 404.

At time 702, the first rising edge on CLK_REF sets DFF 404 and node Atransitions from a logic ‘0’ to a logic ‘1’.

At time 703, a next rising edge of the CLK_FB signal sets DFF 402 andthe UP signal (the output of DFF 402) transitions from a logic ‘0’ to alogic ‘1’. That rising edge of the CLK_FB signal also sets DFF 403 andnode B transitions from a logic ‘0’ to a logic ‘1’.

At time 704, with a logic ‘1’ on node B (the D-input of DFF 401), therising edge of CLK_REF latches a logic ‘1’ at the output of DFF 401.With both outputs (DOWN, UP) of DFFs 401, 402 at a logic ‘1’, a logic‘0’ pulse is generated on the RSTb signal by the reset circuit 416 toreset DFFs 401, 402 and both outputs (DOWN, UP) are set to a logic ‘0’.

After the first transition of the UP signal to a logic ‘1’ to initiallyincrease the delay, the phase detector 412 controls the generation ofthe output signals (UP/DOWN) to further increase or decrease the delayuntil lock is achieved. The phase detection circuit continues toincrease the delay by setting the UP signal to logic ‘1’ as shown attime 705.

FIG. 8 is a schematic diagram of an alternate embodiment of the phasedetection circuit 800 shown in FIG. 4 for use in a DLL in which thedelay is reset to the maximum value at reset. The phase detectorinitialization circuit 806 coupled to the phase detector 412 at node Aand node B ensures the correct ordering of the detection of clock edgesafter reset.

To ensure correct ordering, the phase detector initialization circuit806 disables the operation of the phase detector 412 until after thefirst rising edge of the CLK_FB has been detected after reset. After thephase detector initialization circuit 806 detects the first rising edgeof CLK_FB, the state of the phase detector 412 is set to allow adecrease in the DLL delay. The phase detector initialization circuit 806further delays enabling a increase of the delay by the phase detector412 until the next CLK_REF rising edge to ensure that the delay isalways decreased after a system or power up reset even when there is noinitial phase difference between the clocks. After the initial decreasein the delay, the phase detector 412 operates as described inconjunction with the prior art phase detector described in conjunctionwith FIGS. 2 and 3. By detecting the rising edge of CLK_FB first afterreset, and delaying the detection of the first rising edge of CLK_REFprior to enabling phase detection, the delay is always decreased afterreset. By always automatically decreasing the delay after reset, theno-lock condition in the prior art phase detector described inconjunction with FIGS. 2 and 3 is never encountered.

The phase detector initialization circuit 806 includes two DFFs 802,804. DFF 802 detects the first rising edge of CLK_FB after reset andenables a decrease in the delay by setting node A to a logic ‘1’. DFF804 delays enabling an increase in the delay by holding node B at alogic ‘0’ until after the next rising edge of CLK_REF.

The phase detection circuit 402 includes two DFFs 401, 402 and resetcircuit 416. The output of DFF 802 (node A) is coupled to the D input ofDFF 401 and the output of DFF 804 (node B) is coupled to the D input ofDFF 402. The respective asynchronous reset input of each DFF 401, 402 iscoupled to the output (RSTb) of the reset circuit 416. The RSTb signalis set to a logic ‘0’ to reset DFFs 401, 402 during a reset while theRESETb signal is held at a logic ‘0’ or while both the UP and DOWNsignals are at a logic ‘1’.

The clock input of each DFF 401, 402 is coupled to a respective one ofthe input clock signals (CLK_REF, CLK_FB), with the clock input of DFF401 coupled to CLK_REF and the clock input of DFF 402 coupled to CLK_FB.The output of each DFF 401, 402 is coupled to respective UP/DOWN inputsof a charge pump to increase or decrease the delay based on the detectedphase difference between the clocks.

FIG. 9 is a schematic diagram of an alternate embodiment of the phasedetector initialization circuit. In this embodiment the signals coupledto the data input and asynchronous reset input of DFF 604 which detectsthe first rising edge of CLK_REF after reset differ from the embodimentshown in FIG. 4. The data input to DFF 604 is coupled to RESETb signalinstead of Vdd and the asynchronous reset input is coupled to Vddinstead of the RESETb. DFF 604 is reset after the first rising edge ofCLK_REF when RESETb is at a logic ‘0’. DFF 604 is set with a logic ‘1’on node A after the first rising edge of CLK_REF after RESETbtransitions from a logic ‘0’ to a logic ‘1’. After DFF 604 detects thefirst rising edge of CLK_REF, the operation of the circuit is the sameas described in conjunction with the embodiment shown in FIG. 4.

FIG. 10 is yet another embodiment of the phase detector initializationcircuit. To allow the clocks to stabilize after a reset or on power up,additional DFFs can be added to the phase detector initializationcircuit described in conjunction with FIG. 4 so that more than onerising edge is detected on CLK_REF prior to enabling the phase detectioncircuit, An additional DFF 706 is coupled to DFF 704. CLK_REF is alsocoupled to the clock input of DFF 706. Thus, the transition of node Afrom a logic ‘0’ to a logic ‘1’ occurs after the second rising edge ofCLK_REF is detected by DFF 704. The additional delay (one CLK_REFperiod) allows the clocks (CLK_REF and CLK_FB) to stabilize after thecircuit has been reset. Those skilled in the art will appreciate thatany desired number of stages may be added to further increase the numberof CLK_REF rising edges detected prior to enabling the phase detectioncircuit.

An additional DFF 705 is also coupled between DFF 705 and DFF 701. Theclock input of DFF 705 is coupled to the CLK_FB signal and theasynchronous reset input is coupled to the RESETb signal. The output ofDFF 705 is coupled to the input of DFF 703. The additional DFF 705delays the transition of the DOWN signal from a logic ‘0’ to a logic ‘1’and thus increases the time that the UP signal is initially set at alogic ‘1’ to increase the delay. Those skilled in the art willappreciate that any desired number of stages may be added to furtherincrease the time that the UP signal is held at logic ‘1’.

FIG. 11 is a timing diagram illustrating the operation of the circuit ofFIG. 10. The outputs of DFFs 703, 704 are coupled at nodes A and B torespective inputs of DFFs 401, 402. Prior to time 900, during reset, theRESETb signal is held at a logic ‘0’ and the delay set to a minimumdelay. While the RESETb signal and RSTb signal are at a logic ‘0’ on therespective D-inputs of DFFs 401, 402, 403, 704, 705, 706, a rising edgeon the CLK_FB signal or the CLK_REF signal has no effect on the outputsignals (UP, DOWN).

At time 900, the RESETb signal transitions to a logic ‘1’ allowing theDFFs to change state.

At time 901, the first rising edge on CLK_REF sets DFF 706 and theoutput of DFF 706 transitions from a logic ‘0’ to a logic ‘1’.

At time 902, the second rising edge on CLK_REF sets DFF 704 and node A(the output of DFF 404) transitions from a logic ‘0’ to a logic ‘1’. Alogic ‘1’ on node A enables an increase in the delay through DFF 402 inthe phase detection circuit 412.

At time 903, a subsequent rising edge of the CLK_FB signal sets DFF 402and the UP signal (the output of DFF 402) transitions from a logic ‘0’to a logic ‘1’. The subsequent rising edge of the CLK_FB signal alsosets DFF 705.

At time 904, the next rising edge of the CLK_FB signal sets DFF 703 andthe signal at node B (the output of DFF 403) transitions from a logic‘0’ to a logic ‘1’. While the UP signal is at logic ‘1’, the delay isincreased.

At time 905, with a logic ‘1’ at the input of DFF 401, the next risingedge of CLK_REF latches a logic ‘1’ at the output of DFF 401. With bothoutputs (DOWN, UP) of DFFs 401, 402 at a logic ‘1’, a logic ‘0’ pulse isgenerated on the RSTb signal by the reset circuit 416 to reset DFFs 401,402 and both outputs (DOWN, UP) are set to a logic ‘0’.

In alternate embodiments the delay line can be set to the maximum delay(total delay of all unit cells in the voltage control delay line) onreset and the phase detector can be configured to automatically decreasethe delay. Additionally the present invention has been described usingrising edge triggered flip-flops, however falling edge triggered DFFscan also be used. Further, the invention has been described using avoltage controlled delay line, however digital or tapped delay lines canalso be used.

While this invention has been particularly shown and described withreferences to preferred embodiments thereof, it will be understood bythose skilled in the art that various changes in form and details may bemade therein without departing from the scope of the inventionencompassed by the appended claims.

1-11. (canceled)
 12. A delay locked loop comprising: a delay circuitwhich provides a delay to a reference clock to generate a feedbackclock, the delay circuit having a delay range; a phase detector whichcompares phase of the reference clock and the feedback clock, and, adelay control circuit to change the delay of the delay circuit, and aninitialization circuit which, once the delay locked loop is reset: i)enables the delay control circuit to initially change the delay in adirection away from a first end of the delay range; and ii) enables achange in the delay in an opposite direction toward the first end onlyafter a number of clock cycles later.
 13. The delay locked loop of claim12 wherein the number of clock cycles is an integer number of clockcycles greater than zero.
 14. The delay locked loop of claim 12 whereinthe delay circuit is a digital circuit.
 15. The delay locked loop ofclaim 12 wherein the delay circuit is an analog circuit.
 16. The delaylocked loop of claim 12, further comprising a charge pump.
 17. The delaylocked loop of claim 16, wherein said delay line control circuit furthercontrols the operation of said charge pump.
 18. The delay locked loop ofclaim 12 said delay line control controls the direction of said delaycircuit to produce a positive or negative delay.
 19. The delay lockedloop of claim 12 wherein the first edge of the reference clock is arising edge and the edge of the feedback clock is a rising edge.
 20. Thedelay locked loop of claim 12, further comprising a reset circuitcontrolling the reset of the delay locked loop in response to a resetsignal, the initialization circuit resetting in response to the resetsignal.
 21. The delay locked loop of claim 12, further comprising areset circuit controlling the reset of the delay locked loop in responseto a reset signal, the phase detector resetting in response to the resetsignal.
 22. The delay locked loop of claim 12, wherein theinitialization circuit further comprises an input to receive a resetsignal; and wherein the phase detector further comprises an input toreceive the reset signal.
 23. The delay locked loop of claim 22 whereinthe reset signal is an active-low signal.
 24. A delay locked loopcomprising: a delay circuit which provides a delay to a reference clockto generate a feedback clock, the delay circuit having a delay range; aphase detector which compares phase of the reference clock and thefeedback clock, and, a delay control circuit to change the delay of thedelay circuit, and an initialization circuit which, once the delaylocked loop is reset: i) enables the delay control circuit to initiallychange the delay in a direction away from a first end of the delayrange; and ii) enables a change in the delay in an opposite directiontoward the first end only after a predetermined number of clock cycleslater.
 25. The delay locked loop of claim 24 wherein the number of clockcycles is an integer number of clock cycles greater than zero.
 26. Thedelay locked loop of claim 24 wherein the delay circuit comprises avoltage controlled delay line.
 27. The delay locked loop of claim 24wherein the delay circuit comprises an analog delay circuit.
 28. Thedelay locked loop of claim 24 wherein the delay circuit comprises adigital delay line.
 29. The delay locked loop of claim 24 wherein thefirst end of the delay range is a minimum delay and the direction awayfrom the first end increases the delay and the opposite directiontowards the first end decreases the delay.
 30. The delay locked loop ofclaim 24 wherein when the phase detector is initially changing the delayit is only increasing the delay.
 31. The delay locked loop of claim 30wherein the first edge of the reference clock is a rising edge and theedge of the feedback clock is a rising edge.
 32. The delay locked loopof claim 24, further comprising a reset circuit controlling the reset ofthe delay locked loop in response to a reset signal, the initializationcircuit resetting in response to the reset signal.
 33. The delay lockedloop of claim 24, further comprising a reset circuit controlling thereset of the delay locked loop in response to a reset signal, the phasedetector resetting in response to the reset signal.
 34. The delay lockedloop of claim 24 wherein the initialization circuit further comprises aninput to receive a reset signal; and wherein the phase detector furthercomprises an input to receive the reset signal.
 35. The delay lockedloop of claim 24 wherein the reset signal is an active-low signal.